WO2016052066A1 - Wireless base station, mobile station, wireless communication system, control method for wireless base station and recording medium - Google Patents

Abstract

A wireless base station comprises: a communication unit 101 which communicates with a mobile station that measures the wireless quality of a signal transmitted in each of a plurality of cells; a storage unit 102 which acquires load information relating to the load of a network forming a cell and including a wireless base station; and a control unit 103. The control unit receives information from the mobile station indicating a measurement result of the wireless quality of the signal transmitted in each of the plurality of cells and the state of a battery of the mobile station, determines a signal for wireless quality measurement by the mobile station on the basis of the received information indicating the measurement result of the wireless quality and the state of the battery of the mobile station, and the acquired load information, and notifies the mobile station of the signal determined to be measured.

Description

Radio base station, mobile station, radio communication system, radio base station control method, and recording medium

The present invention relates to a radio base station, a mobile station, a radio communication system, a radio base station control method, and a program.

In recent years, communication areas of a plurality of networks with different communication schemes are overlapped, and a mobile station may be connected to one of the networks and be provided with a communication service. Examples of the communication method described above include GSM (Global System for Mobile Communication), UTRAN (Universal Terrestrial Access Network), and E-UTRAN (Evolved UTRAN).
Along with the increase in traffic in recent years, the installation of small mobile phone base stations and wireless LAN (WLAN: Wireless Local Area Network) base stations has reduced the load on the radio access network including macro base stations. . Also, the load on the core network is reduced by sending the traffic of the mobile station from a small wireless base station or wireless LAN to an external network (Internet) without going through the upper core network of the wireless access network. . A network constructed by combining networks of different communication methods as described above is referred to as Heterogeneous Network (HetNet).

Regarding HetNet, Non-Patent Document 1 (3GPP (3rd Generation Partnership Projet) TR37.834 v12.0.0) describes a method for linking a wireless LAN and a mobile phone network. In this method, the mobile station measures the radio quality of signals transmitted from both the wireless LAN and the cellular phone network. Then, the mobile station determines a network to be connected based on factors such as a wireless quality measurement result in accordance with a policy or threshold set from the mobile phone network or an instruction from the mobile phone network.

Patent Document 1 (Japanese Patent Application Laid-Open No. 2004-260444) discloses a method for realizing seamless handover while reducing the processing load in HetNet. In this method, a mobile station measures the radio quality of signals from radio access stations of a plurality of networks having different communication methods, and determines a connection-destination radio access station based on the measurement result. A network control device provided above the radio access station controls the handover operation of the mobile station based on the radio access station of the connection destination, the network accommodating the radio access station, the moving speed of the mobile station, and the like.
In the methods described in Non-Patent Document 1 and Patent Document 1 described above, the mobile station needs to measure the radio quality of the signal from the network of each communication method. Therefore, the number of signals to be measured for radio quality of the mobile station increases, and the power consumption of the mobile station increases.

Therefore, in Patent Document 2 (International Publication No. 2007/080627), the third generation mobile communication system (3G), the fourth generation mobile communication system (4G), and Super3G positioned between 3G and 4G. A method of suppressing an increase in power consumption of a mobile station in a wireless communication system in which (S3G) communication areas are superimposed is described. In this method, the mobile station selects a signal for measuring the radio quality from each of the 3G, S3G, and 4G signals according to the remaining battery level, and connects to a connection destination from the network corresponding to the signal for which the radio quality is measured. To decide. By selecting a signal for measuring the radio quality, an increase in power consumption of the mobile station can be suppressed as compared with the case of measuring the radio quality of each of the 3G, S3G, and 4G signals.

The problem that the power consumption of a mobile station increases due to an increase in the number of radio quality measurement targets is not limited to HetNet. This problem may also occur in CA (Carrier Aggregation) defined in Non-Patent Document 2 (3GPP TS36.300 v12.1.0).
CA is a technology for transmitting and receiving data using a maximum of 5 carrier carriers (hereinafter referred to as CCs) of 20 MHz. In CA, since a mobile station uses CCs of different frequencies in combination, it is necessary to measure the radio quality of signals in a plurality of frequency bands, and power consumption of the mobile station increases.

In addition, the above-described problem may occur in DC (Dual Connectivity) defined in Non-Patent Document 3 (3GPP TR36.842 v12.0.0).
In the DC, a Master eNB (evolved NodeB) (hereinafter referred to as MeNB) and a Secondary eNB (hereinafter referred to as SeNB) are defined. Then, the mobile station transmits / receives control data to / from a distant MeNB and transmits / receives user data to / from a nearby SeNB. In DC, the mobile station needs to measure the radio quality of a signal transmitted in a cell formed by each of the MeNB and SeNB, and power consumption of the mobile station increases.

JP 2004-260444 A International Publication No. 2007/080627

As described above, the methods described in Patent Document 1 and Non-Patent Document 1 have a problem that the power consumption of the mobile station increases.
With the method described in Patent Document 2, an increase in power consumption of the mobile station can be suppressed. However, in the method described in Patent Document 2, the mobile station selects a radio quality measurement target signal and determines the connection destination as a result of the measurement. Therefore, the method described in Patent Document 2 has a problem that it is impossible to control the measurement target of the radio quality of the mobile station from the radio base station side in consideration of the network load.
For example, the radio quality of a signal from a mobile phone base station in a mobile station is superior to the radio quality of a signal from a wireless LAN base station, but the mobile phone base station is congested and the data from the mobile station is You may not want to accept more. Even in such a case, in the method described in Patent Document 2, the mobile station selects a signal from the mobile phone base station as a measurement target, and as a result, determines the mobile phone base station as a connection destination. May end up.
Also in Non-Patent Documents 2 and 3, a sufficient study on the above-mentioned problem has not been made.
An object of the present invention is to provide a radio base station, a mobile station, a radio communication system, which can control a measurement target of radio quality in a mobile station in consideration of a network load and suppress increase in power consumption of the mobile station, To provide a control method and program for a radio base station.

In order to achieve the above object, the radio base station of the present invention provides:
A communication unit that communicates with a mobile station that measures radio quality of signals transmitted in each of a plurality of cells;
An acquisition unit for acquiring load information related to a load of a network including a wireless base station forming the cell;
The mobile station receives the wireless quality measurement result of the signal transmitted in each of the plurality of cells and the information indicating the battery state of the mobile station from the mobile station via the communication unit, and the radio indicated in the received information Based on the quality measurement result, the battery status of the mobile station, and the load information acquired by the acquisition unit, a signal to be measured for radio quality of the mobile station is determined, and the communication unit is connected to the mobile station. And a control unit for notifying the signal determined as the measurement target.

In order to achieve the above object, the mobile station of the present invention
Battery,
A communication unit for communicating with a radio base station;
A measurement unit for measuring radio quality of signals transmitted in each of a plurality of cells;
Via the communication unit, the wireless unit transmits information indicating the wireless quality measurement result of the signal transmitted in each of the plurality of cells of the measurement unit and the battery state of the mobile station, and the communication unit A control unit that causes the measurement unit to measure the radio quality of the notified signal when the signal of the measurement target of the radio quality is notified from the radio base station via the network.

In order to achieve the above object, the wireless system of the present invention provides:
A mobile station, and a radio base station that communicates with the mobile station,
The mobile station measures the radio quality of a signal transmitted in each of a plurality of cells, and obtains information indicating a measurement result of a radio quality of a signal transmitted in each of the plurality of cells and a battery state of the mobile station. To the radio base station,
The radio base station acquires load information related to a load of a network including the radio base stations forming the cell, the measurement result of the radio quality transmitted from the mobile station, the battery state of the mobile station, and , On the basis of the acquired load information, determine the signal of the measurement target of the radio quality of the mobile station, notify the determined signal of the measurement target to the mobile station,
The mobile station measures the radio quality of the signal notified from the radio base station.

In order to achieve the above object, a radio base station control method of the present invention includes:
Communicate with a mobile station that measures the radio quality of signals transmitted in each of a plurality of cells,
Obtaining load information on the load of the network including the radio base stations forming the cell;
The mobile station receives the radio quality measurement result of the signal transmitted in each of the plurality of cells and the information indicating the battery status of the mobile station, the radio quality measurement result indicated in the received information, the mobile Based on the battery status of the station and the load information acquired by the acquisition unit, a signal to be measured for radio quality of the mobile station is determined, and the signal determined as the measurement target is notified to the mobile station.

In order to achieve the above object, the recording medium of the present invention comprises:
To the computer in the radio base station,
Processing to communicate with a mobile station that measures the radio quality of signals transmitted in each of a plurality of cells;
A process of obtaining load information relating to a load of a network including a radio base station forming the cell;
The mobile station receives the radio quality measurement result of the signal transmitted in each of the plurality of cells and the information indicating the battery status of the mobile station, the radio quality measurement result indicated in the received information, the mobile A process of determining a signal to be measured for radio quality of the mobile station based on the battery status of the station and the load information acquired by the acquisition unit, and notifying the mobile station of the signal determined as the measurement target And a computer-readable recording medium on which a program for executing is recorded.

According to the present invention, it is possible to control the measurement target of the radio quality in the mobile station in consideration of the network load and suppress the increase in power consumption of the mobile station.

It is a figure which shows the structure of the radio | wireless communications system which concerns on the 1st Embodiment of this invention. It is a block diagram which shows the principal part structure of HeNB shown in FIG. It is a block diagram which shows the principal part structure of UE shown in FIG. It is a figure which shows an example of the application environment of this invention. It is a sequence diagram which shows operation | movement of HeNB and UE shown in FIG. It is a figure which shows an example of a structure of a measurement report. It is a flowchart which shows operation | movement of the control part shown in FIG. It is a figure which shows the signal of the measuring object of the radio | wireless quality of UE shown in FIG. It is a figure which shows the structure of the radio | wireless communications system which concerns on the 2nd Embodiment of this invention. It is a block diagram which shows the principal part structure of eNB shown in FIG. It is a figure which shows an example of the application environment of this invention. FIG. 10 is a sequence diagram showing operations of the eNB and UE shown in FIG. 9. It is a figure which shows the structure of the radio | wireless communications system which concerns on the 3rd Embodiment of this invention. It is a block diagram which shows the principal part structure of MeNB shown in FIG. It is a figure which shows an example of the application environment of this invention. It is a sequence diagram which shows operation | movement of MeNB and UE shown in FIG. It is a block diagram which shows the other structure of the wireless base station which concerns on this invention. It is a figure which shows another example of a structure of a measurement report.

Hereinafter, embodiments for carrying out the present invention will be described with reference to the drawings.

(First embodiment)
FIG. 1 is a diagram showing a configuration of a wireless communication system 1 according to the first embodiment of the present invention.
A radio communication system 1 shown in FIG. 1 includes a UE (User Equipment) 2, a HeNB (Home eNB) 11, a HeNB-GW (Home eNB Gateway) 12, (H) eNBs 13 and 14, X2-GW 15, EPC (Evolved Packet Core) 16, PGW (Packet Data Network Gateway) 17, ANDSF (Access Network Discovery and Selection Function) and Node B19, Hde (B), HB (B) 21, RNC (Radio Network Controller) 22 and 3GCN (3rd Generation Core Network) ork) 23, BTS (Base Transceiver Station) 24, BSC (Base Station Controller) 25, 2GCN (2nd Generation Core Network ACK) 26, WLAN AP (Wireless Local Accord) Data Gateway) 28 and PGW 29.

The HeNB 11 is a small radio base station that forms a cell that is a communication area in which radio communication with the UE 2 is possible. The HeNB performs radio communication with the UE 2 located in the cell formed by the HeNB by the LTE (Long Term Evolution) method via the Uu interface.
The HeNB-GW 12 is connected to the HeNB 11 via the S1 interface and manages the HeNB 11.
(H) The eNBs 13 and 14 are HeNBs or eNBs (so-called macro base stations) and are radio base stations that form cells. (H) The eNBs 13 and 14 perform radio communication with the UE 2 located in a cell formed by the eNBs 13 and 14 using the LTE scheme. (H) The eNB 13 is connected to the HeNB 11 via the X2 interface.
The X2-GW 15 is connected to the HeNB 11 and the (H) eNB 14 via the X2 interface. The X2-GW 15 relays communication between the HeNB 11 and the (H) eNB 14.
The HeNB 11, HeNB-GW 12, (H) eNBs 13, 14 and X2-GW 15 constitute an E-UTRAN 3 that is an E-UTRAN network.

The EPC 16 is a core network device corresponding to E-UTRAN3. The EPC 16 is connected to the HeNB-GW 12 and the (H) eNBs 13 and 14 via the S1 interface. The EPC 16 performs authentication, mobility control, bearer management, charging, QoS (Quality of Service) control, and the like.
The PGW 17 is connected to the EPC 16 and is connected to the Internet 7 via the SGi interface. The PGW 17 performs data transfer between the E-UTRAN 3 and the Internet 7.
The ANDSF 18 provides data (for example, policy) to the UE 2 via the S14 interface to assist the UE 2 in discovering and connecting to the network according to the policy defined by the operator. The provision of the data described above is performed in response to an access network discovery information request from the UE 2.

At present, an interface between the ANDSF 18 and other nodes (HeNB11, (H) eNB13, 14, HNB20, RNC22, BSC25, etc.) is not defined. In the following, it is assumed that an interface called “ltf-X” (ltf-X interface) is defined between the ANDSF 18 and other nodes.
In FIG. 1, the HeNB-GW 12 is not an essential configuration. Therefore, (H) eNBs 13 and 14 are connected without going through EPC 16 and HeNB-GW 12. In FIG. 1, X2-GW 15 is not an essential component. Therefore, the HeNB 11 is directly connected to the (H) eNB 13 without passing through the X2-GW 15.

The NodeB 19 is a radio base station (so-called macro base station) that forms a cell. The Node B 19 performs radio communication with the UE 2 located in the cell formed by the Node B 19 using the UTRAN system.
The HNB 20 is a small radio base station that forms a cell. The HNB 20 performs radio communication with the UE 2 located in the cell formed by the HNB 20 using the UTRAN system.
The HNB-GW 21 is connected to the HNB 20 via the lub interface and manages the HNB 20.
The RNC 22 is connected to the NodeB 19 via the lub interface, and is connected to the HNB-GW 21 via the lur interface. The RNC 22 performs management of the NodeB 19 and the HNB 20, handover control, and the like. The RNC 22 is connected to the BSC 25 via the lurg interface.
The NodeB 19, the HNB 20, the HNB-GW 21 and the RNC 22 constitute a UTRAN 4 which is a UTRAN network.

3GCN23 is a core network device corresponding to UTRAN4. The 3GCN 23 is connected to the HNB-GW 21 and the RNC 22 via the lu interface, and is connected to the Internet 7 via the Gi interface. The 3GCN 23 performs data transfer between the UTRAN 4 and the Internet 7.

The BTS 24 is a radio base station that forms a cell. The BTS 24 performs radio communication with the UE 2 located in the cell formed by the BTS 24 using the GSM method.
The BSC 25 is connected to the BTS 24 via the Abis interface, and controls the BTS 24.
The BTS 24 and the BSC 25 constitute a GSM 5 that is a GSM network.

2 GCN 26 is a core network device corresponding to GSM5. The 2GCN 26 is connected to the BSC 25 via the A interface and is connected to the Internet 7 via the Gi interface. The 2GCN 26 performs data transfer between the GSM 5 and the Internet 7.

WLAN AP 27 is a wireless base station (WLAN base station) that forms a cell. The WLAN AP 27 performs wireless communication with the UE 2 located in the cell formed by the WLAN AP 27 using the WLAN method. The WLAN AP 27 constitutes a WLAN 6 that is a WLAN network.

The ePDG 28 is a core network device corresponding to the WLAN 6. The ePDG 28 relays traffic between the WLAN AP 27 and the PGW 29.
The PGW 29 is connected to the ePDG 28 and is connected to the Internet 7 via the SGi interface. The PGW 29 performs data transfer between the WLAN 6 and the Internet 7.
Note that wireless communication between the WLAN AP 27 and the UE 2 is performed using the SWu interface or the S2c interface. When the SWu interface is used, traffic may flow directly between the WLAN AP 27 and the PGW 29 via the S2a interface, or may flow via the ePDG 28 via the SWn interface and the S2b interface. When the S2c interface is used, traffic may flow directly between the WLAN AP 27 and the PGW 29 via the S2c interface, or may flow via the ePDG 28 via the S2c interface.

UE2 is a mobile station that can wirelessly communicate with wireless base stations that constitute each network of E-UTRAN3, UTRAN4, GSM5, and WLAN6. UE2 measures the radio quality of signals transmitted in a plurality of cells (cells formed by radio base stations constituting each network), and transmits the measurement results to the radio base station in communication.

Next, the configuration of the HeNB 11 and the UE 2 will be described. Note that the configuration of other nodes is well known to those skilled in the art and is not directly related to the present invention, so the description thereof is omitted.

First, the configuration of the HeNB 11 will be described.
FIG. 2 is a block diagram illustrating a main configuration of the HeNB 11.
The HeNB 11 illustrated in FIG. 2 includes a communication unit 101, a storage unit 102, and a control unit 103. The storage unit 102 is an example of an acquisition unit.
The communication unit 101 performs radio communication with the UE2.
The storage unit 102 stores various information. Further, the storage unit 102 acquires and stores load information related to the load of each network such as E-UTRAN3, UTRAN4, GSM5 and WLAN6, which are radio access networks, and the corresponding core network.
The control unit 103 receives information indicating the measurement result of the radio quality of the signal transmitted in each of the plurality of cells and the state of the battery of the UE 2 from the UE 2 via the communication unit 101. The control unit 103 determines a radio quality measurement target signal of the UE 2 based on the measurement result of the radio quality indicated in the received information, the state of the battery of the UE 2 and the load information stored in the storage unit 102. And the control part 103 transmits the message which shows the signal determined as a measuring object to UE2 via the communication part 101. FIG.

Next, the configuration of UE2 will be described.
FIG. 3 is a block diagram illustrating a main configuration of the UE 2.
The UE 2 illustrated in FIG. 3 includes a communication unit 201, a measurement unit 202, a storage unit 203, a battery 204, and a control unit 205.
The communication unit 201 performs radio communication with radio base stations (HeNB11, (H) eNB13, 14, NodeB19, HNB20, BTS24, WLAN AP27).
The measurement unit 202 measures the radio quality of signals transmitted through a plurality of cells (cells formed by radio base stations constituting each network) received via the communication unit 201.
The storage unit 203 stores various information.
The battery 204 supplies power for operating the UE2.
The control unit 205 transmits information indicating the measurement result of the wireless quality of the measurement unit 202 and the state of the battery 204 to the HeNB 11 via the communication unit 201. In addition, when the control unit 205 receives a message indicating the radio quality measurement target signal from the HeNB 11 via the communication unit 201, the control unit 205 causes the measurement unit 202 to measure the radio quality of the signal indicated in the received message.

Next, operations of the HeNB 11 and the UE 2 will be described.
In the following, as shown in FIG. 4, UE2 is located in E-UTRAN cell 11a, which is a cell formed by HeNB11, and has established a connection (RRC (Radio Resource Control) connection) with HeNB11. To do. The UE 11 is also located in a cell formed by each of the (H) eNBs 13 and 14, the HNB 20, the BTS 24, and the WLAN AP 27. In the following, the cells formed by (H) eNB13, (H) eNB14, HNB20, BTS24, and WLAN AP27 are respectively an E-UTRAN cell 13a, an E-UTRAN cell 14a, a UTRAN cell 20a, a GSM cell 24a, and a WLAN cell 27a. Called. Hereinafter, it is assumed that the frequency X is used in the E-UTRAN cell 11a, the frequency Y is used in the E-UTRAN cell 13a, and the frequency Z is used in the E-UTRAN cell 14a.

FIG. 5 is a sequence diagram illustrating operations of the HeNB 11 and the UE 2.
First, the control unit 103 of the HeNB 11 requests a measurement report from the UE 2 via the communication unit 101 (step S11). Here, the control unit 103 requests measurement of radio quality of signals transmitted in each of the E-UTRAN cells 11a, 13a, 14a, the UTRAN cell 20a, the GSM cell 24a, and the WLAN cell 27a in which the UE 2 is located.

In addition, the storage unit 102 acquires and stores load information related to the network load in advance. Specifically, for example, the storage unit 102 acquires and stores load information (load information related to the core network) of the EPC 16, 3GCN 23, 2GCN 26, and ePDG 28 configuring the core network. In addition, the storage unit 102 acquires and stores load information (load information related to the radio access network) such as (H) eNBs 13 and 14, Node B 19, RNC 22, BTS 24, BSC 25, and WLAN AP 27 configuring the radio access network.
Specific examples of the load information related to the core network include information such as BUSCA (Busy Hour Call Attempts) and the number of connections. Specific examples of load information related to the radio access network include available radio resources and interface capacity.

Note that the load information can be acquired from other radio base stations, host devices, management devices, and the like. Since a specific method for acquiring load information is not directly related to the present invention, detailed description is omitted, but there is a method as described below. For example, there is a method of exchanging information on available radio resources between different types of radio access networks according to the procedure called RAN Information Management defined in Non-Patent Document 2. Also, information on available radio resources is exchanged between radio access networks of the same system or different systems via interfaces such as lur, lurg, lur which are interfaces between HNBs not shown in FIG. There is a way to do it.

When the measurement report is requested from the HeNB 11, the control unit 205 of the UE 2 causes the measurement unit 202 to measure the radio quality of the signal transmitted in each cell specified by the measurement report. Specific examples of radio quality include RSRP (Reference Signal Received Power), RSRQ (Reference Signal Received Quality), and Ec / Io (desired signal power / total received power). The control unit 205 stores the measurement result of the measurement unit 202 in the storage unit 203. Further, the control unit 205 measures the state (remaining amount) of the battery 204 and stores the measurement result in the storage unit 203.

Next, the control unit 205 transmits, via the communication unit 201, information indicating the measurement result of the radio quality of each cell stored in the storage unit 203 and the state (remaining amount) of the battery 204 to the HeNB 11 as a measurement report. (Step S13).
FIG. 6 is a diagram illustrating an example of a configuration of a measurement report.
UE2 transmits the information which added the parameter (battery level part of FIG. 6) called the Battery Level to the measurement report (MeasResults Information) prescribed | regulated by 3GPP TS36.331 v12.1.0. The battery level indicates the remaining amount of the battery 204 as a percentage.

Referring to FIG. 5 again, when the control unit 103 of the HeNB 11 receives the measurement report transmitted from the UE 2 via the communication unit 101, the control unit 103 stores the received measurement report in the storage unit 102. The control unit 103 uses the measurement report and the load information stored in the storage unit 102 as inputs of the evaluation function, and determines a measurement target signal of the UE 2 based on the output of the evaluation function.

FIG. 7 is a flowchart illustrating an operation when the control unit 103 determines a signal to be measured for wireless quality.
In the following description, it is assumed that the load information of the core network stored in the storage unit 102 indicates that the load is relatively large in the order of EPC16, 3GCN23, 2GCN26, and ePDG28. That is, it is assumed that the correlation of the load of each node is EPC16>3GCN23>2GCN26> ePDG28. Further, the radio load information of the radio access network stored in the storage unit 102 can be relatively used in the order of the GSM cell 24a, the UTRAN cell 20a, the E-UTRAN cell 13a, the WLAN cell 27a, and the E-UTRAN cell 14a. Assume that the amount of radio resources is small. That is, the correlation of the amount of available radio resources is assumed to be GSM cell 24a <UTRAN cell 20a <E-UTRAN cell 13a <WLAN cell 27a <E-UTRAN cell 14a. In the following, it is assumed that the radio quality of each cell is GSM cell 24a> UTRAN cell 20a> E-UTRAN cell 13a> E-UTRAN cell 14a> WLAN cell 27a.

When the radio quality of each cell is GSM cell 24a> UTRAN cell 20a> E-UTRAN cell 13a> E-UTRAN cell 14a> WLAN cell 27a (step S21), the control unit 103 proceeds to the process of step S22.
In step S22, the control unit 103 determines whether or not the remaining amount of the battery 204 of the UE2 indicated in the measurement report is equal to or greater than a threshold value.
When it is determined that the remaining amount of the battery 204 is equal to or greater than the threshold (step S22: Yes), the control unit 103 determines whether or not the congestion of the EPC 16, 3GCN23, and 2GCN26 is equal to or greater than the threshold (step S23). .
When it is determined that the congestion of the EPC 16, 3GCN 23, and 2GCN 26 is equal to or greater than the threshold (step S23: Yes), the control unit 103 proceeds to the process of step S25 described later. When it is determined that the congestion of the EPC 16, 3GCN 23, and 2GCN 26 is not equal to or greater than the threshold (step S23: No), the control unit 103 proceeds to the process of step S26 described later.
When it is determined that the remaining amount of the battery 204 is not equal to or greater than the threshold (step S22: No), the control unit 103 determines whether the congestion of the EPC 16, 3GCN 23, and 2GCN 26 is equal to or greater than the threshold (step S24).
When it is determined that the congestion of the EPC 16, 3GCN 23, 2GCN 26 is equal to or greater than the threshold value (step S24: Yes), the control unit 103 proceeds to the process of step S27 described later. When it is determined that the congestion of the EPC 16, 3GCN 23, and 2GCN 26 is not equal to or greater than the threshold (step S24: No), the control unit 103 proceeds to the process of step S28 described later.

Hereinafter, the processes of steps S25 to S28 will be described.
First, the process of step S25 will be described.
When the process of step S25 is performed, the remaining amount of the battery 204 of the UE2 is equal to or greater than the threshold value (there is a remaining amount), and the congestion of the EPC 16, 3GCN23, 2GCN26 is equal to or greater than the threshold value (congested). is there.
In this case, the control unit 103 determines the radio quality measurement target signal of the UE 2 in consideration of the following a) to d).
a) 2GCN 26 is congested, but the degree is relatively small (load information on the core network)
b) The ePDG 28 is not congested.
c) The available radio resources are relatively small in the GSM cell 24a but relatively large in the WLAN cell 27a (load information on the radio access network).
d) The radio quality of the GSM cell 24a is relatively good, and the radio quality of the WLAN cell 27a is relatively poor.
Here, in c), the evaluation of the WLAN cell 27a is high (the available radio resources are large), and the evaluation of the GSM cell 24a is low (the available radio resources are small). Also, in d), the WLAN cell 27a has a high evaluation (good wireless quality) and the GSM cell 24a has a low evaluation (not good wireless quality). Therefore, a part or all of the evaluation of the WLAN cell 27a and the GSM cell 24a is canceled. However, the control unit 103 considers that the evaluation of the WLAN cell 27a and the GSM cell 24a is higher than the evaluation of other cells in a) and b), and the signal transmitted in the WLAN cell 27a and the GSM cell 24a A signal to be transmitted is determined as a signal to be measured for wireless quality. And the control part 103 memorize | stores in the memory | storage part 102 that these signals were determined as a signal of the radio | wireless quality measurement object of UE2. Note that the determination logic described above is merely an example, and the control unit 103 may determine a signal to be measured for the radio quality of the UE 2 according to another determination logic.

Next, the process of step S26 will be described.
When the process of step S26 is performed, the remaining amount of the battery 204 of the UE2 is equal to or greater than the threshold (there is a remaining amount), and the congestion of the EPC16, 3GCN23, 2GCN26 is not equal to or greater than the threshold (not congested). .
In this case, the control unit 103 determines a signal to be measured for the radio quality of the UE 2 in consideration of the following a) to c).
a) The EPC 16 is not congested.
b) The E-UTRAN cell 13a and the E-ETRAN cell 14a have a certain amount of available radio resources (load information on the radio access network).
c) The radio quality of the E-UTRAN cell 13a and the E-ETRAN cell 14a is not relatively bad.
Here, in a), the GSM cell 24a, the E-UTRAN cell 13a, and the E-UTRAN 14a have the same evaluation in terms of “not congested”. Further, in b), the E-UTRAN cell 13a and the E-UTRAN 14a are more highly rated (larger available radio resources) than the GSM cell 24a. In c), the GSM cell 24a, the E-UTRAN cell 13a, and the E-UTRAN 14a have the same evaluation in that they are “not relatively bad”. As a result of these considerations, the control unit 103 determines the signal of the frequency Y transmitted in the E-UTRAN cell 13a and the signal of the frequency Z transmitted in the E-ETRAN cell 14a as radio quality measurement target signals. . And the control part 103 memorize | stores in the memory | storage part 102 that these signals were determined as a signal of the radio | wireless quality measurement object of UE2. Note that the determination logic described above is merely an example, and the control unit 103 may determine a signal to be measured for the radio quality of the UE 2 according to another determination logic.

Next, the process of step S27 will be described.
When the process of step S27 is performed, the remaining amount of the battery 204 of the UE2 is not equal to or greater than the threshold value (there is no remaining amount), and the congestion of the EPC16, 3GCN23, 2GCN26 is equal to or greater than the threshold value (congested). is there.
In this case, the control unit 103 determines a signal to be measured for the radio quality of the UE 2 in consideration of the following a) to e).
a) 2GCN 26 is congested, but the degree is relatively small (load information on the core network).
b) The ePDG 28 is not congested.
c) The available radio resources are relatively small in the GSM cell 24a but relatively large in the WLAN cell 27a (load information on the radio access network).
d) The radio quality of the GSM cell 24a is relatively good, and the radio quality of the WLAN cell 41-1 is relatively poor.
e) Since there is no room in the remaining amount of the battery 204, it is necessary to narrow down the signal to be measured as much as possible.
Here, the control unit 103 weights c) and e) among the above a) to e) with the evaluation function, and determines a signal to be measured for the radio quality of the UE2. As a result, the control unit 103 determines a signal transmitted in the WLAN cell 27a as a wireless quality measurement target. Then, the control unit 103 stores in the storage unit 102 that the signal transmitted in the WLAN cell 41-1 has been determined as the signal to be measured for the radio quality of the UE2.

Next, the process of step S28 will be described.
When the process of step S28 is performed, the remaining amount of the battery 204 of the UE2 is not equal to or greater than the threshold value (there is no remaining amount), and the congestion of the EPC16, 3GCN23, 2GCN26 is not equal to or greater than the threshold value (no congestion) .
In this case, the control unit 103 determines the radio quality measurement target signal of the UE 2 in consideration of the following a) to d).
a) The EPC 16 is not congested.
b) The E-UTRAN cell 13a and the E-ETRAN cell 14a have a certain amount of available radio resources (load information on the radio access network).
c) The radio quality of the E-UTRAN cell 13a and the E-ETRAN cell 14a is not relatively bad, and the radio quality of the E-UTRAN cell 13a is better than that of the E-ETRAN cell 14a.
d) Since there is no room in the remaining amount of the battery 204, it is necessary to narrow down the signal to be measured as much as possible.
Here, the control unit 103 weights c) and d) among the above a) to d) in the evaluation function to determine a signal to be measured for the radio quality of the UE2. As a result, the control unit 103 determines a signal of frequency Y transmitted in the E-UTRAN cell 13a as a signal to be measured for radio quality. Then, the control unit 103 stores in the storage unit 102 that the signal of the frequency Y transmitted in the E-UTRAN cell 13a has been determined as the signal to be measured for the radio quality of the UE2.

FIG. 7 shows an example of the operation of the control unit 103 when the radio quality of each cell is GSM cell 24a> UTRAN cell 20a> E-UTRAN cell 13a> E-UTRAN cell 14a> WLAN cell 27a. It is a thing. For each state of radio quality of each cell, the control unit 103 determines a signal to be measured for the radio quality of UE2 in accordance with a decision logic that also considers the state of the battery of UE2.

Referring to FIG. 5 again, the control unit 103 notifies the signal determined as the measurement target of the radio quality of the UE 2 stored in the storage unit 102 via the communication unit 101 (step S15). That is, the control unit 103 transmits a message indicating the communication method and frequency of the signal determined as a wireless quality measurement target to the UE 2 via the communication unit 101.

When the control unit 205 of the UE 2 is notified of the radio quality measurement target signal via the communication unit 201, the control unit 205 causes the measurement unit 202 to measure the radio quality of the notified signal (step S16).
FIG. 8 is a diagram illustrating measurement targets of the radio quality of the UE 2 before and after the notification from the HeNB 11. In FIG. 8, it is assumed that a signal transmitted in the WLAN cell 27a and a signal transmitted in the GSM cell 24a are notified as signals for measurement of radio quality.
As shown in FIG. 8, before notification from the HeNB 11, the UE 2 measures the radio quality of each of the E-UTRAN cells 11a, 13a, 14a, the UTRAN cell 20a, the GSM cell 24a, and the WLAN cell 27a. On the other hand, after the notification from the HeNB 11, the UE 2 measures only the radio quality of the GSM cell 24a and the WLAN cell 27a. As a result, the number of radio quality measurement target signals is reduced, and an increase in power consumption of the UE 2 can be suppressed.

Thus, according to the present embodiment, the HeNB 11 includes the communication unit 101 that communicates with the UE 2, the storage unit 102 that acquires and stores network load information, and the control unit 103. The control unit 103 receives information indicating the radio quality measurement results of the plurality of cells and the status of the battery 204 of the UE 2 from the UE 2, and based on the radio quality measurement results, the status of the battery 204, and the load information, the radio of the UE 2 Determine the signal whose quality is to be measured. And the control part 103 notifies UE2 of the signal determined as a measuring object.

Therefore, not only the state of the battery 204 of the UE 2 but also the network load is taken into consideration, and the measurement target of the radio quality of the UE 2 can be controlled to suppress an increase in power consumption of the UE 2.
In addition, by controlling the measurement target of the radio quality in consideration of the network load, the signal of the cell having many available radio resources can be set as the measurement target of the radio quality, and the success rate of the handover of the UE 2 is improved. be able to.
In addition, by controlling the wireless quality measurement target in consideration of the network load, it is possible to select a cell in a network with a smaller load as compared with other networks as a connection destination, thereby improving throughput. .
Moreover, interference can be suppressed and the throughput of the whole radio | wireless communications system 1 can be improved by making only some signals into a measurement object among the signals of the several cell from which a communication system and frequency differ.

In the present embodiment, the wireless communication system 1 has been described using an example including E-UTRAN3, UTRAN4, GSM5, and WLAN6. However, the present invention is not limited to this, and the wireless communication system 1 includes a plurality of the above-described multiple communication systems. You may have only a part of the network. For example, the wireless communication system 1 may include only the GSM 5 and the WLAN 6.

(Second Embodiment)
FIG. 9 is a diagram showing a configuration of a wireless communication system 1a according to the second embodiment of the present invention.
The wireless communication system 1a of the present embodiment is different from the wireless communication system 1 of the first embodiment in that the HeNB 11 and the HeNB-GW 12 are deleted and the eNB 30 is added.
The eNB 30 is a radio base station that forms a cell. The eNB 30 performs radio communication with the UE 2 located in the cell formed by the eNB 30 using the LTE scheme. Here, in this embodiment, CA shall be performed between eNB30 and UE2.

Next, the configuration of the eNB 30 will be described.
FIG. 10 is a block diagram illustrating a main configuration of the eNB 30.
The eNB 30 illustrated in FIG. 10 includes a communication unit 301, a storage unit 302, and a control unit 303. The storage unit 302 is an example of an acquisition unit.
The communication unit 301 performs radio communication with the UE2.
The storage unit 302 stores various information such as load information.
The control unit 303 receives information indicating the measurement result of the radio quality and the state of the battery 204 of the UE 2 from the UE 2 via the communication unit 301. The control unit 303 determines the measurement target CC of the UE 2 radio quality based on the measurement result of the radio quality indicated in the received information, the state of the battery 204 of the UE 2 and the load information stored in the storage unit 302. And the control part 303 transmits the message which shows CC determined as a measuring object to UE2 via the communication part 301. FIG.

Next, operations of the eNB 30 and the UE 2 will be described.
In the following, as shown in FIG. 11, the e-UTRAN 30 uses an E-UTRAN cell 30a that uses a frequency band A including two CCs as unit frequency bands and an E-U that uses a frequency band B that includes three CCs. It is assumed that a UTRAN cell 30b is formed. Also, UE2 is located in E-UTRAN cell 30a and has established an RRC connection, but is also included in the coverage of E-UTRAN cell 30b.

FIG. 12 is a sequence diagram illustrating operations of the eNB 30 and the UE 2.
First, the control unit 303 of the eNB 30 requests a measurement report from the UE 2 via the communication unit 301 (step S31). Here, the control unit 303 requests measurement of the radio quality of the E-UTRAN cells 30a and 30b. The storage unit 302 acquires and stores load information in advance. Note that the content of the load information to be acquired and the method for acquiring the load information are the same as in the first embodiment, and thus the description thereof is omitted.

When a measurement report is requested from the eNB 30, the control unit 205 of the UE 2 causes the measurement unit 202 to measure the radio quality of signals transmitted in the E-UTRAN cells 30a and 30b specified in the measurement report (step S32). As described above, the frequency band A including two CCs is used in the E-UTRAN cell 30a, and the frequency band B including three CCs is used in the E-UTRAN cell 30b. The measuring unit 202 measures the radio quality for each CC in the frequency band of each cell.
The control unit 205 causes the storage unit 203 to store the measurement result (wireless quality of each cell) of the measurement unit 202. Further, the control unit 205 measures the state (remaining amount) of the battery 204 and stores the measurement result in the storage unit 203.

Next, the control unit 205 transmits information indicating the measurement result of the radio quality of each cell stored in the storage unit 203 and the state (remaining amount) of the battery 204 to the eNB 30 via the communication unit 201 as a measurement report. (Step S33). Note that, similarly to the first embodiment, the control unit 205 transmits information obtained by adding a parameter called Battery Level indicating the remaining amount of the battery 204 as a percentage to a wireless quality measurement report (MeasResults information).

When the control unit 303 of the eNB 30 receives the measurement report transmitted from the UE 2 via the communication unit 301, the control unit 303 stores the received measurement report in the storage unit 302. And the control part 303 determines CC used for UE2 based on the measurement report and load information which are memorize | stored in the memory | storage part 302. FIG. For example, when the remaining amount of the battery 204 of the UE2 is low, the control unit 303 does not use the CC included in the frequency band B used in the E-UTRAN 30b and is included in the frequency band A used in the E-UTRAN 30a. It is determined that only one CC is used. In addition, for example, when the radio quality of the E-UTRAN 30b is poor or when the radio resources available in the E-UTRAN cell 30b are low, the control unit 303 determines not to use the CC included in the frequency band B.
The control unit 303 determines the CC that is determined to be used as the CC that is the measurement target of the radio quality of the UE 2 and stores the CC in the storage unit 302.

Next, the control unit 303 notifies the CC determined as the radio quality measurement target of the UE 2 stored in the storage unit 302 via the communication unit 301 (step S35). That is, the control unit 303 transmits a message indicating the CC determined as the wireless quality measurement target to the UE 2 via the communication unit 101.

When the control unit 205 of the UE 2 is notified of the CC to be measured for wireless quality via the communication unit 201, the control unit 205 stores the notified CC in the storage unit 203. Then, the control unit 205 causes the measurement unit 202 to measure the CC radio quality stored in the storage unit 203. In addition, the control unit 205 causes the communication unit 201 to continue communication with the eNB 30 using the CC stored in the storage unit 203.

As described above, according to the present embodiment, the eNB 30 includes the communication unit 301 that communicates with the UE 2, the storage unit 302 that acquires and stores network load information, and the control unit 303. When the CA is performed, the control unit 303 receives the measurement result of the radio quality of the cell and the information indicating the state of the battery 204 from the UE 2, and based on the measurement result of the radio quality, the state of the battery 204 and the load information, the UE 2 The CC to be measured for the wireless quality is determined. And the control part 103 notifies CC determined as a measuring object to UE2.

Therefore, not only the state of the battery 204 of the UE 2 but also the network load is taken into consideration, and the CC that is the measurement target of the radio quality of the UE 2 can be controlled to suppress an increase in power consumption of the UE 2.
Moreover, interference can be suppressed and the throughput of the whole radio | wireless communications system 1a can be improved by making only some CC into measurement object among CC used by CA.

(Third embodiment)
FIG. 13 is a diagram showing a configuration of a wireless communication system 1b according to the third embodiment of the present invention. The wireless communication system 1b of the present embodiment is different from the wireless communication system 1a of the second embodiment in that the eNB 30 is changed to the eNB 31 and (H) the eNB 13 is changed to the eNB 32.
The eNBs 31 and 32 are radio base stations that form a cell. The eNBs 31 and 32 perform radio communication with the UE 2 located in a cell formed by the eNBs 31 and 32 using the LTE system via the Uu interface. In the present embodiment, the UE 2 is connected simultaneously with the eNBs 31 and 32, and the DC is performed with the eNB 31 as the MeNB and the eNB 32 as the SeNB. Below, eNB31 is called MeNB31 and eNB32 is called SeNB32.

Next, the configuration of the MeNB 31 will be described. In addition, since the structure of SeNB32 is the same as that of MeNB31, description is abbreviate | omitted.
FIG. 14 is a block diagram illustrating a main configuration of the MeNB 31.
The MeNB 31 illustrated in FIG. 14 includes a communication unit 401, a storage unit 402, and a control unit 403. The storage unit 402 is an example of an acquisition unit.
The communication unit 401 performs radio communication with the UE2.
The storage unit 402 stores various information such as load information.
The control unit 403 receives information indicating the measurement result of the radio quality and the state of the battery 204 of the UE 2 from the UE 2 via the communication unit 401. The control unit 403 determines a signal to be measured for the radio quality of the UE 2 based on the measurement result of the radio quality indicated in the received information, the state of the battery 204 of the UE 2 and the load information stored in the storage unit 402. And the control part 403 transmits the message which shows the signal determined as a measuring object to UE2 via the communication part 401. FIG.

Next, operations of the MeNB 31 and the UE 2 will be described.
Hereinafter, as illustrated in FIG. 15, the MeNB 31 is assumed to form a serving cell group (hereinafter, referred to as MSG: Master Cell Group) 31 a. Moreover, SeNB32 shall form the serving cell group (henceforth SSG: Secondary Cell Group) 32a. In addition, UE2 is present in the coverage of MSG31a, is present in the coverage of SSG32a, and establishes connection with MeNB31 and SeNB32 to perform DC. Hereinafter, it is assumed that the frequency 留 is used in the MSG 31a and the frequency 硫 is used in the SSG 32a.

FIG. 16 is a sequence diagram showing operations of the MeNB 31 and the UE2.
First, the control unit 403 of the MeNB 31 requests a measurement report from the UE 2 via the communication unit 401 (step S41). Here, the control unit 403 requests measurement of radio quality of signals transmitted in the MSG 31a and the SSG 32a. In addition, the storage unit 402 acquires and stores load information in advance. Note that the content of the load information to be acquired and the method for acquiring the load information are the same as in the first embodiment, and thus the description thereof is omitted.

When the measurement report is requested from the MeNB 31, the control unit 205 of the UE 2 causes the measurement unit 202 to measure the radio quality of the signal transmitted in the MSG 31a and the SSG 32a specified in the measurement report (Step S42).
The control unit 205 causes the storage unit 203 to store the measurement result of the measurement unit 202 (wireless quality of signals transmitted in the MSG 31a and the SSG 32a). Further, the control unit 205 measures the state (remaining amount) of the battery 204 and stores the measurement result in the storage unit 203.

Next, the control unit 205 transmits the measurement result of the wireless quality stored in the storage unit 203 and information indicating the state (remaining amount) of the battery 204 to the MeNB 31 as a measurement report via the communication unit 201 (step). S43). Note that, similarly to the first embodiment, the control unit 205 transmits information obtained by adding a parameter called Battery Level indicating the remaining amount of the battery 204 as a percentage to a wireless quality measurement report (MeasResults information).

When the control unit 403 of the MeNB 31 receives the measurement report transmitted from the UE 2 via the communication unit 401, the control unit 403 stores the received measurement report in the storage unit 402. Then, the control unit 403 determines whether or not to allow the UE 2 to use the SSG 32a based on the measurement report and the load information stored in the storage unit 402. For example, the control unit 403 determines not to allow the use of the SSG 32a when the remaining amount of the battery 204 is low or when the radio resources available in the SSG 32a are low. For example, when UE2 performs DC and uses a service with a small amount of data transmission / reception such as VoLTE (Voice over LTE), both control data and user data are transmitted to and received from MeNB31. There is no problem. By doing so, transmission of ACK / NACK to both MeNB 31 and SeNB 32 and measurement of radio quality in MSG 31a and SSG 32a become unnecessary, so that the power consumption of UE 2 can be reduced.

When it is determined that the use of the SSG 32a is not permitted, the control unit 403 indicates that the use of the SSG 32a is not permitted and that the signal of the frequency α transmitted in the MSG 31a is determined as a signal to be measured for the radio quality of the UE2. The data is stored in the storage unit 402. In addition, when the control unit 403 determines to permit the use of the SSG 32a, the control unit 403 determines the signal of the frequency α transmitted in the MSG 31a and the signal of the frequency β transmitted in the SSG 32a as signals for measurement of the radio quality of the UE2. That is, the storage unit 402 stores the information.

Next, the control unit 403 notifies the signal determined as the measurement target of the radio quality of the UE 2 stored in the storage unit 302 via the communication unit 401 (step S45). Specifically, when the control unit 403 determines to permit the use of the SSG 32a, the control unit 403 transmits the signal of the frequency α transmitted in the MSG 31a determined as the wireless quality measurement target and the signal of the frequency β transmitted in the SSG 32a. Send a message to indicate. In addition, when the control unit 403 determines not to permit the use of the SSG 32a, the control unit 403 transmits a signal indicating that the use of the SSG 32a is not permitted and a signal of the frequency α transmitted in the MSG 31a determined as the wireless quality measurement target. To do. Hereinafter, it is assumed that the control unit 403 determines not to permit the use of the SSG 32a.

When the control unit 205 of the UE 2 is notified of the radio quality measurement target signal (the signal of the frequency α transmitted in the MSG 31 a) via the communication unit 201, the control unit 205 stores the notified signal in the storage unit 203. In addition, since the control unit 205 is notified that the use of the SSG 32a is not permitted, the control unit 205 stores in the storage unit 203 that the SSG 32a is not used. Then, the control unit 205 causes the communication unit 201 to release the connection with the SeNB 32 and causes the measurement unit 202 to measure the radio quality of the signal with the frequency α transmitted in the MSG 31a.

As described above, according to the present embodiment, the MeNB 31 includes the communication unit 401 that communicates with the UE 2, the storage unit 402 that acquires and stores network load information, and the control unit 403. The control unit 403 receives the measurement results of the radio quality of the MSG 31a and the SSG 32a and the information indicating the status of the battery 204 of the UE 2 from the UE 2, and uses the SSG 32a based on the measurement result of the radio quality, the status of the battery 204 and the load information. Determine whether or not. And the control part 103 determines the signal of the measuring object of the radio | wireless quality of UE2 according to the determination, and notifies the signal determined as measuring object to UE2.

Therefore, not only the state of the battery 204 of the UE 2 but also the network load is taken into consideration to determine whether or not the SSG 32a can be used, and according to the determination, the signal to be measured for the radio quality of the UE 2 is determined. The increase in power consumption can be suppressed.
Moreover, by reducing the frequency band of the signal to be measured by the UE 2, it is possible to suppress interference and improve the overall throughput of the radio communication system 1b.

In addition, in 1st Embodiment, HeNB11 demonstrated using the example which acquires the measurement result of radio | wireless quality from UE2, However, It is not restricted to this. As a modification, as illustrated in FIG. 17, the HeNB 11 may include a measurement unit 104 that measures the radio quality of the cells of each network, and the control unit 103 may acquire the measurement result of the radio quality from the measurement unit 104. .

Moreover, in 1st Embodiment, HeNB11 demonstrated using the example which transmits a measurement request | requirement with respect to UE2 which has established RRC connection, However, it is not restricted to this. As a modification, the HeNB 11 may transmit a measurement request to a UE that has not established an RRC connection located in the cell, using broadcast information of the cell that it forms.
Moreover, in 1st Embodiment, HeNB11 may determine whether the WLAN cell 27a is registered as an adjacent cell of the cell which self forms according to an O & M (Operation & Maintenance) procedure. Then, the HeNB 11 may set a signal transmitted in the WLAN cell 27a as a measurement target if the WLAN cell 27a is registered, and not a measurement target if the WLAN cell 27a is not registered.

In the first to third embodiments, the example in which the measurement target of the radio quality of the UE 2 is determined in consideration of the load on the core network and the radio access network has been described. However, the present invention is not limited to this. Absent. As a modification, considering the load on the interface between radio base stations such as the X2 interface used at the time of handover, the load on the CPU (Central Processing Unit) of the radio base station that forms the cell that can be the handover destination, etc. Good. When these loads are high, the success rate of handover decreases. For this reason, by avoiding signals transmitted in cells formed by radio base stations with a high load on the interface and CPU to be connected from being measured for radio quality, handover to cells with a low success rate of handover is possible. Trials can be reduced.

Also, as a modification, the type of service being used may be input to the evaluation function. For example, when a voice call is used, a signal of the GSM cell 24a or the UTRAN cell 20a is used as a measurement target, and when a streaming service for viewing content is used, the E-UTRAN cells 13a and 14b are used. Signals may be measured.

As a modification, the HeNB 11 may receive data (for example, policy) provided by the ANDSF 18 to the UE 2 via the ltf-X interface, and may use this data as an input to the evaluation function.

Further, in the second embodiment, when the remaining capacity of the battery 204 is sufficient, the CC used by the UE 2 may be increased. Further, in the third embodiment, after it is determined that the use of the SCG 32a is not permitted, the use of the SCG 32a may be permitted when the remaining capacity of the battery 204 is sufficient. By increasing the CC used by the UE 2 or permitting the use of the SCG 32a, it is possible to improve the throughput.

In the first to third embodiments, the description has been given using the example of using the parameter called “Battery Level” indicating the remaining amount of the battery 204 as a percentage as the information related to the state of the battery 204. However, the present invention is not limited to this. is not. As a modification, the absolute value of the remaining amount of the battery 204 (discharge capacity (mAh), estimated value of sustainable time, etc.), date of manufacture, type, model number, etc. may be used as information regarding the state of the battery 204. . Further, an IMEISV (International Mobile Equipment Software Version) including the manufacturer, model, serial number, software revision, and the like of the UE 2 may be used as the input of the evaluation function.
For example, if the absolute value of the remaining capacity of the battery 204 has a margin, if the UE 2 is an old product from the model, date of manufacture, serial number, and software revision, and the power consumption is large, the battery 204 The remaining amount may be evaluated lower.

In the first to third embodiments, the UE 2 has been described using an example in which information on the state of the battery 204 is reported together with the measurement result of the radio quality in response to reception of the measurement request from the radio base station. However, it is not limited to this. As a modification, the UE 2 may transmit information related to the state of the battery 204 when the remaining amount of the battery 204 is equal to or greater than a predetermined threshold or is equal to or less than the predetermined threshold.

In the first to third embodiments, the description has been made using the example in which the information about the state of the battery 204 (battery level) is notified from the UE 2 to the radio base station. However, the present invention is not limited to this. When the present invention is applied to UTRAN, a parameter “battery Level” (dotted line portion in FIG. 18) is added to a message suitable for 3GPP TS25.331 v12.1.0 as shown in FIG. May be.

Further, although the first embodiment has been described based on LTE, the present invention may be applied to other networks such as UTRAN, GSM, WLAN, and CDMA (Code Division Multiple Access) 2000.

In the first to third embodiments, when MIMO (Multi input Multi Output) is used, the number of antennas to be used may be reduced according to the output of the evaluation function. By carrying out like this, reduction of the power consumption of UE2 can be aimed at.

Also, in LTE-Advanced, a technology called 3D beamforming is being studied. This technique reduces inter-cell interference by horizontal and vertical beam forming, and forms another beam between UEs 2 in the same cell. In the first to third embodiments, when 3D beamforming is used, the shape of the generated beam may be controlled according to the output of the evaluation function. For example, the beam shape may be increased if the remaining amount of the battery 204 is large, and the beam shape may be decreased if the remaining amount of the battery 204 is small. By carrying out like this, reduction of the power consumption of UE2 can be aimed at.

In the third embodiment, the UE 2 has been described using an example in which the connection with the SeNB 32 is released and the communication with the MeNB 31 is continued. However, the present invention is not limited to this. As a modification, the UE 2 may release the connection between the MeNB 31 and the UE 2 and continue the connection with the SeNB 32.

In the first to third embodiments, the UE 2 has been described using an example in which processing according to the message is performed in response to reception of the message notifying the measurement target signal. However, the present invention is not limited thereto. It is not a thing. For example, the radio base station may include a timer in the message, and the UE 2 may start the timer after receiving the message and perform processing according to the message when the timer expires. Also, the radio base station includes a timer and a counter threshold in the message. The UE 2 starts a timer after receiving the message, increments the counter value when the timer expires, performs processing according to the message, and starts the timer again after the processing. You may repeat until it exceeds.
Further, the first to third embodiments may be appropriately combined.

The method performed in the radio base station and the mobile station (UE) of the present invention may be applied to a program for causing a computer to execute. In addition, the program can be stored in a storage medium and can be provided to the outside via a network.

Some or all of the above embodiments may be described as in the following supplementary notes, but are not limited to the following.

(Appendix 1)
A communication unit that communicates with a mobile station that measures radio quality of signals transmitted in each of a plurality of cells;
An acquisition unit for acquiring load information related to a load of a network including a wireless base station forming the cell;
The mobile station receives the wireless quality measurement result of the signal transmitted in each of the plurality of cells and the information indicating the battery state of the mobile station from the mobile station via the communication unit, and the radio indicated in the received information Based on the quality measurement result, the battery status of the mobile station, and the load information acquired by the acquisition unit, a signal to be measured for radio quality of the mobile station is determined, and the communication unit is connected to the mobile station. And a control unit that notifies the signal determined as the measurement target.

(Appendix 2)
The signal transmitted in each of the plurality of cells is a signal of a different communication method,
The control unit determines a radio quality measurement target signal of the mobile station, and communicates with the mobile station via the communication unit at least a communication method of the measurement target signal and a frequency band of the measurement target signal. The radio base station according to appendix 1, wherein a message indicating one of the messages is transmitted.

(Appendix 3)
The signal transmitted in each of the plurality of cells is a signal in a predetermined frequency band including one or a plurality of component carriers that are unit frequency bands,
The control unit determines a component carrier to be measured for radio quality of the mobile station, and transmits a message indicating the component carrier to be measured to the mobile station via the communication unit. 1. A radio base station according to 1.

(Appendix 4)
The signal transmitted in each of the plurality of cells is a signal from each of the plurality of cells to which the mobile station is connected,
The control unit determines a radio quality measurement target signal of the mobile station, and a cell in which a frequency band of the measurement target signal and a signal that is not the measurement target are transmitted to the mobile station via the communication unit 2. The radio base station according to appendix 1, wherein a message indicating at least one of releasing the connection with is transmitted.

(Appendix 5)
Battery,
A communication unit for communicating with a radio base station;
A measurement unit for measuring radio quality of signals transmitted in each of a plurality of cells;
Via the communication unit, the wireless unit transmits information indicating the wireless quality measurement result of the signal transmitted in each of the plurality of cells of the measurement unit and the battery state of the mobile station, and the communication unit And a control unit that causes the measurement unit to measure the radio quality of the notified signal when the signal of the radio quality measurement target is notified from the radio base station via the radio base station. .

(Appendix 6)
The signal transmitted in each of the plurality of cells is a signal of a different communication method,
When the control unit receives a message indicating at least one of a communication method of a signal to be measured and a frequency band of the signal to be measured from the radio base station via the communication unit, the control unit adds the message to the measurement unit. The mobile station according to appendix 5, wherein the radio quality of a signal in the indicated communication method or frequency band is measured.

(Appendix 7)
The signal transmitted in each of the plurality of cells is a signal in a predetermined frequency band including one or a plurality of component carriers that are unit frequency bands,
When the control unit receives a message indicating a component carrier to be measured from the radio base station via the communication unit, the control unit causes the measurement unit to measure the radio quality of the component carrier indicated in the message. The mobile station according to appendix 5.

(Appendix 8)
The signal transmitted in each of the plurality of cells is a signal from each of the plurality of cells to which the mobile station is connected,
The control unit receives a message indicating at least one of stopping a connection with a cell to which a frequency band of the signal to be measured and a signal not to be measured are transmitted from the radio base station via the communication unit. Then, the measurement unit causes the radio quality of the signal indicated in the message to be measured, and causes the communication unit to release a connection with a cell to which a signal that is not a measurement target is transmitted. .

(Appendix 9)
A mobile station, and a radio base station that communicates with the mobile station,
The mobile station measures the radio quality of a signal transmitted in each of a plurality of cells, and obtains information indicating a measurement result of a radio quality of a signal transmitted in each of the plurality of cells and a battery state of the mobile station. To the radio base station,
The radio base station acquires load information related to a load of a network including the radio base stations forming the cell, the measurement result of the radio quality transmitted from the mobile station, the battery state of the mobile station, and , On the basis of the acquired load information, determine the signal of the measurement target of the radio quality of the mobile station, notify the determined signal of the measurement target to the mobile station,
The radio communication system, wherein the mobile station measures radio quality of a signal notified from the radio base station.

(Appendix 10)
The signal transmitted in each of the plurality of cells is a signal of a different communication method,
The radio base station determines a signal to be measured for radio quality of the mobile station, and transmits a message indicating at least one of a communication method of the signal to be measured and a frequency band of the signal to be measured to the mobile station. And
When the mobile station receives from the radio base station a message indicating at least one of the communication method of the signal to be measured and the frequency band of the signal to be measured, the signal of the communication method or frequency band indicated in the message The wireless communication system according to appendix 9, wherein the wireless quality is measured.

(Appendix 11)
The signal transmitted in each of the plurality of cells is a signal in a predetermined frequency band including one or a plurality of component carriers that are unit frequency bands,
The radio base station determines a component carrier for measurement of radio quality of the mobile station, and transmits a message indicating the component carrier for measurement to the mobile station,
The wireless communication system according to appendix 9, wherein when the mobile station receives a message indicating the component carrier to be measured from the wireless base station, the mobile station measures the wireless quality of the component carrier indicated in the message.

(Appendix 12)
The signal transmitted in each of the plurality of cells is a signal from each of the plurality of cells to which the mobile station is connected,
The radio base station determines a signal to be measured for radio quality of the mobile station and releases at least one of a frequency band of the signal to be measured and a connection with a cell to which the signal not to be measured is transmitted. Send a message indicating
When the mobile station receives a message from the radio base station indicating at least one of a frequency band of the signal to be measured and a connection to a cell to which a signal not to be measured is transmitted, the mobile station indicates the message. The wireless communication system according to appendix 9, wherein the wireless quality of the received signal is measured and the connection with the cell to which the signal not to be measured is transmitted is released.

(Appendix 13)
Communicate with a mobile station that measures the radio quality of signals transmitted in each of a plurality of cells,
Obtaining load information on the load of the network including the radio base stations forming the cell;
The mobile station receives the radio quality measurement result of the signal transmitted in each of the plurality of cells and the information indicating the battery status of the mobile station, the radio quality measurement result indicated in the received information, the mobile Determining a signal of a measurement target of radio quality of the mobile station based on a battery state of the station and load information acquired by the acquisition unit, and notifying the mobile station of the signal determined as the measurement target A control method of a radio base station characterized by the above.

(Appendix 14)
To the computer in the radio base station,
Processing to communicate with a mobile station that measures the radio quality of signals transmitted in each of a plurality of cells;
A process of obtaining load information relating to a load of a network including a radio base station forming the cell;
The mobile station receives the radio quality measurement result of the signal transmitted in each of the plurality of cells and the information indicating the battery status of the mobile station, the radio quality measurement result indicated in the received information, the mobile A process of determining a signal to be measured for radio quality of the mobile station based on the battery status of the station and the load information acquired by the acquisition unit, and notifying the mobile station of the signal determined as the measurement target And a program characterized in that the program is executed.

Although the present invention has been described with reference to the embodiments, the present invention is not limited to the above-described embodiments. Various changes that can be understood by those skilled in the art can be made to the configuration and details of the present invention within the scope of the present invention. This application claims the priority on the basis of Japanese application Japanese Patent Application No. 2014-199733 for which it applied on September 30, 2014, and takes in those the indications of all here.

1 Wireless communication system 2 UE
3 E-UTRAN
4 UTRAN
5 GSM
6 WLAN
11 HeNB
12 HeNB-GW
13, 14 (H) eNB
15 X2-GW
16 EPC
17,29 PGW
18 ANDSF
19 NodeB
20 HNB
21 HNB-GW
22 RNC
23 3GCN
24 BTS
25 BSC
26 GCN
27 WLAN AP
28 ePDG
30 eNB
31 MeNB
32 SeNB
101, 301, 401 Communication unit 102, 302, 402 Storage unit 103, 303, 403 Control unit 201 Communication unit 202 Measurement unit 203 Storage unit 204 Battery 205 Control unit

Claims (10)

1. A communication unit that communicates with a mobile station that measures radio quality of signals transmitted in each of a plurality of cells;
   An acquisition unit for acquiring load information related to a load of a network including a wireless base station forming the cell;
   The mobile station receives the wireless quality measurement result of the signal transmitted in each of the plurality of cells and the information indicating the battery state of the mobile station from the mobile station via the communication unit, and the radio indicated in the received information Based on the quality measurement result, the battery status of the mobile station, and the load information acquired by the acquisition unit, a signal to be measured for radio quality of the mobile station is determined, and the communication unit is connected to the mobile station. And a control unit that notifies the signal determined as the measurement target.
2. The signal transmitted in each of the plurality of cells is a signal of a different communication method,
   The control unit determines a radio quality measurement target signal of the mobile station, and communicates with the mobile station via the communication unit at least a communication method of the measurement target signal and a frequency band of the measurement target signal. The radio base station according to claim 1, wherein a message indicating one is transmitted.
3. The signal transmitted in each of the plurality of cells is a signal in a predetermined frequency band including one or a plurality of component carriers that are unit frequency bands,
   2. The radio according to claim 1, wherein the control unit determines a component carrier that is a measurement target of radio quality of the mobile station, and transmits a message indicating the component carrier of the measurement target to the mobile station via the communication unit. base station.
4. The signal transmitted in each of the plurality of cells is a signal from each of the plurality of cells to which the mobile station is connected,
   The control unit determines a radio quality measurement target signal of the mobile station, and a cell in which a frequency band of the measurement target signal and a signal that is not the measurement target are transmitted to the mobile station via the communication unit The radio base station according to claim 1, which transmits a message indicating at least one of releasing the connection with.
5. Battery,
   A communication unit for communicating with a radio base station;
   A measurement unit for measuring radio quality of signals transmitted in each of a plurality of cells;
   Via the communication unit, the wireless unit transmits information indicating the wireless quality measurement result of the signal transmitted in each of the plurality of cells of the measurement unit and the battery state of the mobile station, and the communication unit And a control unit that causes the measurement unit to measure the radio quality of the notified signal when a signal of a radio quality measurement target is notified from the radio base station via the radio base station.
6. The signal transmitted in each of the plurality of cells is a signal of a different communication method,
   When the control unit receives a message indicating at least one of a communication method of a signal to be measured and a frequency band of the signal to be measured from the radio base station via the communication unit, the control unit adds the message to the measurement unit. The mobile station according to claim 5, wherein radio quality of a signal in a indicated communication method or frequency band is measured.
7. The signal transmitted in each of the plurality of cells is a signal in a predetermined frequency band including one or a plurality of component carriers that are unit frequency bands,
   The said control part makes the said measurement part measure the radio | wireless quality of the component carrier shown by the said message, if the message which shows the component carrier of a measuring object is received from the said wireless base station via the said communication part. Mobile stations.
8. A mobile station, and a radio base station that communicates with the mobile station,
   The mobile station measures the radio quality of a signal transmitted in each of a plurality of cells, and obtains information indicating a measurement result of a radio quality of a signal transmitted in each of the plurality of cells and a battery state of the mobile station. To the radio base station,
   The radio base station acquires load information related to a load of a network including the radio base stations forming the cell, the measurement result of the radio quality transmitted from the mobile station, the battery state of the mobile station, and , On the basis of the acquired load information, determine the signal of the measurement target of the radio quality of the mobile station, notify the determined signal of the measurement target to the mobile station,
   The mobile station is a radio communication system for measuring radio quality of a signal notified from the radio base station.
9. Communicate with a mobile station that measures the radio quality of signals transmitted in each of a plurality of cells,
   Obtaining load information on the load of the network including the radio base stations forming the cell;
   The mobile station receives the radio quality measurement result of the signal transmitted in each of the plurality of cells and the information indicating the battery status of the mobile station, the radio quality measurement result indicated in the received information, the mobile A radio for determining a signal to be measured for radio quality of the mobile station based on the battery status of the station and the load information acquired by the acquisition unit, and notifying the mobile station of the signal determined as the measurement target Base station control method.
10. To the computer in the radio base station,
    Processing to communicate with a mobile station that measures the radio quality of signals transmitted in each of a plurality of cells;
    A process of obtaining load information relating to a load of a network including a radio base station forming the cell;
    The mobile station receives the radio quality measurement result of the signal transmitted in each of the plurality of cells and the information indicating the battery status of the mobile station, the radio quality measurement result indicated in the received information, the mobile A process of determining a signal to be measured for radio quality of the mobile station based on the battery status of the station and the load information acquired by the acquisition unit, and notifying the mobile station of the signal determined as the measurement target And a computer-readable recording medium on which a program for executing is recorded.
    
    

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